Systems and methods for optical target based indoor vehicle navigation

ABSTRACT

Vehicles, systems, and methods for navigating or tracking the navigation of a materials handling vehicle along a surface that may include a camera and vehicle functions to match two-dimensional image information from camera data associated with the input image of overhead features with a plurality of global target locations of a warehouse map to generate a plurality of candidate optical targets, an optical target associated with each global target location and a code; filter the targets to determine a candidate optical target; decode the target to identify the associated code; identify an optical target associated with the identified code; determine a camera metric relative to the identified optical target and the position and orientation of the identified optical target in the warehouse map; calculate a vehicle pose based on the camera metric; and navigate the materials handling vehicle utilizing the vehicle pose.

CROSS REFERENCE TO RELATED APPLICATIONS

The present specification is a continuation of Ser. No. 16/280,736,filed Feb. 20, 2019, which claims priority to U.S. Provisional PatentApplication Ser. No. 62/634,219, filed Feb. 23, 2018, each entitled“SYSTEMS AND METHODS FOR OPTICAL TARGET BASED INDOOR VEHICLENAVIGATION,” the entireties of which are incorporated by referencedherein.

TECHNICAL FIELD

The present specification generally relates to systems and methods forproviding global localization for industrial vehicles based on overheadfeatures and, more specifically, to systems and methods for utilizationof a global localization to analyze overhead optical targets in awarehouse to track the location of an industrial vehicle with a known orunknown location.

BACKGROUND

In order to move items about an industrial environment, workers oftenutilize industrial vehicles, including for example, forklift trucks,hand and motor driven pallet trucks, and/or other materials handlingvehicles. The industrial vehicles can be configured as an automatedguided vehicle or a manually guided vehicle that navigates through theenvironment. In order to facilitate automated guidance, navigation, orboth, the industrial vehicle may be adapted for localization within theenvironment. That is the industrial vehicle can be adapted with sensorsand processors for determining the location of the industrial vehiclewithin the environment such as, for example, pose and position of theindustrial vehicle.

SUMMARY

In one embodiment, a materials handling vehicle may include a camera, avehicular processor, a drive mechanism configured to move the materialshandling vehicle along an inventory transit surface, a materialshandling mechanism configured to store and retrieve goods in a storagebay of a warehouse, and vehicle control architecture in communicationwith the drive and materials handling mechanisms. The camera may becommunicatively coupled to the vehicular processor and captures an inputimage of overhead features. The vehicular processor of the materialshandling vehicle executes vehicle functions to (i) retrieve an initialset of camera data from the camera, the initial set of camera datacomprising two-dimensional image information associated with the inputimage of overhead features, and (ii) match the two-dimensional imageinformation from the initial set of camera data with a plurality ofglobal target locations of a warehouse map to generate a plurality ofcandidate optical targets. The global target locations of the warehousemap may be associated with a mapping of the overhead features, thewarehouse map may be configured to store a position and orientation ofan optical target associated with each global target location, and eachoptical target may be associated with a code. The vehicle functions mayfurther be to (iii) filter the plurality of candidate optical targets todetermine a candidate optical target, (iv) decode the candidate opticaltarget to identify the code associated with the candidate opticaltarget, (v) identify an optical target associated with the identifiedcode, (vi) determine a camera metric comprising representations of adistance and an angle of the camera relative to the identified opticaltarget and the position and orientation of the identified optical targetin the warehouse map, (vii) calculate a vehicle pose based on the camerametric, and (viii) navigate the materials handling vehicle utilizing thevehicle pose.

In another embodiment, a materials handling vehicle may include acamera, a vehicular processor, a drive mechanism configured to move thematerials handling vehicle along an inventory transit surface, amaterials handling mechanism configured to store and retrieve goods in astorage bay of a warehouse, and vehicle control architecture incommunication with the drive and materials handling mechanisms. Thecamera may be communicatively coupled to the vehicular processor andcaptures an input image of overhead features. The vehicular processor ofthe materials handling vehicle executes vehicle functions to (i)retrieve an initial set of camera data from the camera, the initial setof camera data comprising two-dimensional image information associatedwith the input image of overhead features, and (ii) match thetwo-dimensional image information from the initial set of camera datawith a plurality of global target locations of a warehouse map togenerate a plurality of candidate optical targets. The global targetlocations of the warehouse map may be associated with a mapping of theoverhead features, the warehouse map may be configured to store aposition and orientation of an optical target associated with eachglobal target location, and each optical target may be associated with acode. Each optical target may include a plurality of point light sourcesmounted on a bar that is configured for attachment to a ceiling as anoverhead feature of the overhead features, and the plurality of pointlight sources comprise a light pattern as the code for each respectiveoptical target. The vehicle functions may further be to (iii) filter theplurality of candidate optical targets to determine a candidate opticaltarget, (iv) decode the candidate optical target to identify the codeassociated with the candidate optical target, (v) identify an opticaltarget associated with the identified code, (vi) determine a camerametric comprising representations of a distance and an angle of thecamera relative to the identified optical target and the position andorientation of the identified optical target in the warehouse map, (vii)calculate a vehicle pose based on the camera metric, and (viii) trackthe navigation of the materials handling vehicle along the inventorytransit surface, navigate the materials handling vehicle along theinventory transit surface in at least a partially automated manner, orboth, utilizing the vehicle pose.

In yet another embodiment, a method of navigating or tracking thenavigation of a materials handling vehicle along an inventory transitsurface may include disposing a materials handling vehicle upon aninventory transit surface of a warehouse, wherein the materials handlingvehicle comprises a camera, a vehicular processor, a drive mechanismconfigured to move the materials handling vehicle along the inventorytransit surface, a materials handling mechanism configured to store andretrieve goods in a storage bay of the warehouse, and vehicle controlarchitecture in communication with the drive and materials handlingmechanisms. The method may further include utilizing the drive mechanismto move the materials handling vehicle along the inventory transitsurface, capturing an input image of overhead features of the warehousevia the camera as the materials handling vehicle moves along theinventory transit surface, and retrieving an initial set of camera datafrom the camera, the initial set of camera data comprisingtwo-dimensional image information associated with the input image ofoverhead features. The method may further include matching thetwo-dimensional image information from the initial set of camera datawith a plurality of global target locations of a warehouse map togenerate a plurality of candidate optical targets, wherein the globaltarget locations of the warehouse map are associated with a mapping ofthe overhead features, the warehouse map is configured to store aposition and orientation of an optical target associated with eachglobal target location, and each optical target is associated with acode. The method may further include filtering the plurality ofcandidate optical targets to determine a candidate optical target,decoding the candidate optical target to identify the code associatedwith the candidate optical target, identifying an optical targetassociated with the identified code, determining a camera metriccomprising representations of a distance and an angle of the camerarelative to the identified optical target and the position andorientation of the identified optical target in the warehouse map,calculating a vehicle pose based on the camera metric, and navigatingthe materials handling vehicle utilizing the vehicle pose.

These and additional features provided by the embodiments describedherein will be more fully understood in view of the following detaileddescription, in conjunction with the drawings.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

The embodiments set forth in the drawings are illustrative and exemplaryin nature and not intended to limit the subject matter defined by theclaims. The following detailed description of the illustrativeembodiments can be understood when read in conjunction with thefollowing drawings, where like structure is indicated with likereference numerals and in which:

FIG. 1 depicts a vehicle for localization according to one or moreembodiments shown and described herein;

FIG. 2 depicts an exemplary optical target according to one or moreembodiments shown and described herein;

FIG. 3 depicts a plurality of active target patterns for the exemplaryoptical target of FIG. 2 according to one or more embodiments shown anddescribed herein;

FIG. 4 depicts a flowchart of an exemplary method for camera featureextraction and application and validation of a global localizationmethod within a localization process according to one or moreembodiments shown and described herein;

FIG. 5 depicts a flowchart overview of an exemplary method for a globallocalization method according to one or more embodiments shown anddescribed herein;

FIG. 6 depicts a flowchart overview of another exemplary method for aglobal localization method according to one or more embodiments shownand described herein; and

FIG. 7 depicts a flowchart overview of another yet exemplary method fora global localization method according to one or more embodiments shownand described herein.

DETAILED DESCRIPTION

The embodiments described herein generally relate to localizationtechniques for extracting features from overhead features including, butnot limited to, optical targets as described herein. Localization isutilized herein to refer to any of a variety of system configurationsthat enable active tracking of a vehicle location in a warehouse,industrial facility, or other environment. The concepts of the presentdisclosure are not limited to any particular localization systemconfiguration and are deemed to be applicable to any of a variety ofconventional and yet-to-be developed localization systems. As will bedescribed in greater detail further below, a localization system may beused alongside a global target localization method (GTLM) and/orvalidation system such that, if an industrial vehicle is lost throughthe localization system method, the GTLM may be utilized to recover thevehicle, and the validation system may be utilized to check the accuracyof the recovery before publishing a new current vehicle location.Additionally or alternatively, the GTLM may be utilized as alocalization system itself as well as a recovery system, and/or thevalidation system may be used with the localization systems and/or theGTLM systems. Such localization systems may include those described inU.S. Pat. No. 9,349,181 issued on May 24, 2016, entitled LOST VEHICLERECOVERY UTILIZING ASSOCIATED FEATURE PAIRS, and U.S. Pat. No. 9,984,467entitled VEHICLE POSITIONING OR NAVIGATION UTILIZING ASSOCIATED FEATUREPAIRS, issued on May 29, 2018, both of which are incorporated byreference herein in their entirety. Any inconsistencies in the manner inwhich particular technical terms or phrases are defined in thesereferences, as compared to the content of the present application,should be interpreted with primary reference to the manner in which theterms or phrases are defined in the present application.

Embodiments described herein generally relate to such localizationtechniques for a materials handling vehicle in a warehouse environment.For the purposes of defining and describing the concepts and scope ofthe present disclosure, it is noted that a “warehouse” encompasses anyindoor or otherwise covered facility in which materials handlingvehicles transport goods including, but not limited to, warehousesintended primarily for the storage of goods, such as those where singleor multi-level warehouse racks or storage units are arranged in aislesor otherwise, and manufacturing facilities where goods are transportedabout the facility by materials handling vehicles for use in one or moremanufacturing processes.

Thus, the localization systems may be used to localize and/or navigatean industrial vehicle through a building structure, such as a warehouse.Suitably, the overhead features such as optical targets as describedherein as well as lighting may be mounted in or on a ceiling of abuilding. However, in some embodiments the overhead features may also oralternatively be suspended from a ceiling or wall via suitablestructure. In some embodiments, a camera can be mounted to an industrialvehicle (e.g., automated guided vehicle or a manually guided vehicle)that navigates through a warehouse. The input image can be any imagecaptured from the camera prior to extracting features from the image.

Referring now to FIG. 1, a vehicle 100 can be configured to navigatethrough an industrial facility such as a warehouse 110. The vehicle 100can comprise a materials handling vehicle including a drive mechanism tomove the materials handling vehicle along an inventory transit surface,a materials handling mechanism configured to store and retrieve goods ina storage bay of an industrial facility, and vehicle controlarchitecture in communication with the drive and materials handlingmechanisms. The vehicle 100 can comprise an industrial vehicle forlifting and moving a payload such as, for example, a forklift truck, areach truck, a turret truck, a walkie stacker truck, a tow tractor, apallet truck, a high/low, a stacker-truck, trailer loader, a sideloader,a fork hoist, or the like. The industrial vehicle can be configured toautomatically or manually navigate an inventory transit surface such asa surface 122 of the warehouse 110 along a desired path. Accordingly,the vehicle 100 can be directed forwards and backwards by rotation ofone or more wheels 124. Additionally, the vehicle 100 can be caused tochange direction by steering the one or more wheels 124. Optionally, thevehicle can comprise operator controls 126 for controlling functions ofthe vehicle such as, but not limited to, the speed of the wheels 124,the orientation of the wheels 124, or the like. The operator controls126 can comprise controls that are assigned to functions of the vehicle100 such as, for example, switches, buttons, levers, handles, pedals,input/output device, or the like. It is noted that the term “navigate”as used herein can mean controlling the movement of a vehicle from oneplace to another.

The vehicle 100 can further comprise a camera 102 for capturing overheadimages such as input images of overhead features. The camera 102 can beany device capable of capturing the visual appearance of an object andtransforming the visual appearance into an image. Accordingly, thecamera 102 can comprise an image sensor such as, for example, a chargecoupled device, complementary metal-oxide-semiconductor sensor, orfunctional equivalents thereof. In some embodiments, the vehicle 100 canbe located within the warehouse 110 and be configured to captureoverhead images of the ceiling 112 of the warehouse 110. In order tocapture overhead images, the camera 102 can be mounted to the vehicle100 and focused to the ceiling 112. For the purpose of defining anddescribing the present disclosure, the term “image” as used herein canmean a representation of the appearance of a detected object. The imagecan be provided in a variety of machine readable representations suchas, for example, JPEG, JPEG 2000, TIFF, raw image formats, GIF, BMP,PNG, Netpbm format, WEBP, raster formats, vector formats, or any otherformat suitable for capturing overhead objects.

The ceiling 112 of the warehouse 110 can comprise overhead features suchas overhead optical targets 130 and overhead lights such as, but notlimited to, ceiling lights 114 for providing illumination from theceiling 112 or generally from above a vehicle operating in thewarehouse. The ceiling lights 114 can comprise substantially rectangularlights such as, for example, skylights 116, fluorescent lights, or thelike; and may be mounted in or suspended from the ceiling or wallstructures so as to provide illumination from above. As used herein, theterm “skylight” can mean an aperture in a ceiling or roof fitted with asubstantially light transmissive medium for admitting daylight, such as,for example, air, glass, plastic or the like. While skylights can comein a variety of shapes and sizes, the skylights described herein caninclude “standard” long, substantially rectangular skylights that may ormay not be split by girders or crossbars into a series of panels.Alternatively, skylights can comprise smaller, discrete skylights ofrectangular or circular shape that are similar in size to a bedroomwindow, i.e., about 30 inches by about 60 inches (about 73 cm by about146 cm). Alternatively or additionally, the ceiling lights 114 cancomprise substantially circular lights such as, for example, roundlights 118, merged lights 120, which can comprise a plurality ofadjacent round lights that appear to be a single object, or the like.Thus, overhead lights or ‘ceiling lights’ include sources of natural(e.g. sunlight) and artificial (e.g. electrically powered) light.

The embodiments described herein can comprise one or more vehicularprocessors such as processors 104 communicatively coupled to the camera102. The one or more processors 104 can execute machine readableinstructions to implement any of the methods or functions describedherein automatically. Memory 106 for storing machine readableinstructions can be communicatively coupled to the one or moreprocessors 104, the camera 102, or any combination thereof. The one ormore processors 104 can comprise a processor, an integrated circuit, amicrochip, a computer, or any other computing device capable ofexecuting machine readable instructions or that has been configured toexecute functions in a manner analogous to machine readableinstructions. The memory 106 can comprise RAM, ROM, a flash memory, ahard drive, or any non-transitory device capable of storing machinereadable instructions.

The one or more processors 104 and the memory 106 may be integral withthe camera 102. Alternatively or additionally, each of the one or moreprocessors 104 and the memory 106 can be integral with the vehicle 100.Moreover, each of the one or more processors 104 and the memory 106 canbe separated from the vehicle 100 and the camera 102. For example, amanagement server, server, or a mobile computing device can comprise theone or more processors 104, the memory 106, or both. It is noted thatthe one or more processors 104, the memory 106, and the camera 102 maybe discrete components communicatively coupled with one another withoutdeparting from the scope of the present disclosure. Accordingly, in someembodiments, components of the one or more processors 104, components ofthe memory 106, and components of the camera 102 can be physicallyseparated from one another. The phrase “communicatively coupled,” asused herein, means that components are capable of exchanging datasignals with one another such as, for example, electrical signals viaconductive medium, electromagnetic signals via air, optical signals viaoptical waveguides, or the like.

Thus, embodiments of the present disclosure may comprise logic or analgorithm written in any programming language of any generation (e.g.,1GL, 2GL, 3GL, 4GL, or 5GL). The logic or an algorithm can be written asmachine language that may be directly executed by the processor, orassembly language, object-oriented programming (OOP), scriptinglanguages, microcode, etc., that may be compiled or assembled intomachine readable instructions and stored on a machine readable medium.Alternatively or additionally, the logic or algorithm may be written ina hardware description language (HDL). Further, the logic or algorithmcan be implemented via either a field-programmable gate array (FPGA)configuration or an application-specific integrated circuit (ASIC), ortheir equivalents.

As is noted above, the vehicle 100 can comprise or be communicativelycoupled with the one or more processors 104. Accordingly, the one ormore processors 104 can execute machine readable instructions to operateor replace the function of the operator controls 126. The machinereadable instructions can be stored upon the memory 106. Accordingly, insome embodiments, the vehicle 100 can be navigated automatically by theone or more processors 104 executing the machine readable instructions.In some embodiments, the location of the vehicle can be monitored by thelocalization system as the vehicle 100 is navigated.

For example, the vehicle 100 can automatically navigate along thesurface 122 of the warehouse 110 along a desired path to a desiredposition based upon a localized position of the vehicle 100. In someembodiments, the vehicle 100 can determine the localized position of thevehicle 100 with respect to the warehouse 110. The determination of thelocalized position of the vehicle 100 can be performed by comparingimage data to map data. The map data can be stored locally in the memory106, which can be updated periodically, or map data provided by a serveror the like. In embodiments, an industrial facility map comprises aplurality of three-dimensional global feature points associated with amapping of the overhead features. Given the localized position and thedesired position, a travel path can be determined for the vehicle 100.Once the travel path is known, the vehicle 100 can travel along thetravel path to navigate the surface 122 of the warehouse 110.Specifically, the one or more processors 104 can execute machinereadable instructions to perform localization system functions andoperate the vehicle 100. In one embodiment, the one or more processors104 can adjust the steering of the wheels 124 and control the throttleto cause the vehicle 100 to navigate the surface 122.

Referring to FIG. 2, an optical target 130 is shown as an arrangement ofpoint light sources. In embodiments, the optical target 130 may includeangular power characteristics and be suitable for detection at longranges. As a non-limiting example, the point light sources of theoptical target 130 may include a plurality of light emitting diodes(LEDs). The LEDs may be utilized with and covered by respective angulardiffusion lenses to provide angular power characteristics. The angulardiffusion lenses may be batwing lenses or the like. In otherembodiments, such angular diffusion lenses may not be used such that theLEDs appear most bright right below the optical target 130 but fade inbrightness when viewed from a side angle with respect to the opticaltarget 130. Use of the angular diffusion lenses allow for an attenuationof the direct downward brightness of an LED and an increase in anassociated angular sideways brightness to have angular emissioncharacteristics. With such angular emission characteristics for an LEDcovered by an angular diffusion lens, higher energy is emitted towardangular side directions rather than directly downwards when the LED isfacing downwardly, for example. A radiation pattern may be such that, asa non-limiting example, at 10 meters distance the LEDs utilizing angulardiffusion lenses appear with a similar brightness as compared to viewingthe LEDS from directly below. Such a radiation pattern may ensure flatfield radiation of a warehouse floor above which the optical target 130is mounted and the LEDs are directed toward within, for example, a 60degree cone that is centered at a downwardly directed LED. A detectionrange may then be double (i.e., 1/cos(60°)) the difference between acamera height mounted on a vehicle and a height of an active opticaltarget 130 when mounted on a ceiling infrastructure of a warehouseenvironment and directed downwardly toward the warehouse floor. Otherdetection ranges for the optical target 130 are possible within thescope of this disclosure.

The optical target 130 may include a variety of structures suitable formounting to ceiling infrastructure of a warehouse environment. In someembodiments, the optical target 130 may include a circular shape, asquare shape, or other suitable mounting shape. Any two or threedimensional arrangement of LEDs on the optical target 130 that may ormay not be equidistantly spaced is contemplated within the scope of thisdisclosure. For example, a square arrangement of LEDs on the opticaltarget 130 may be considered a two-dimensional arrangement.Additionally, a single LED mounting for the optical target 130 or amultiple LED mounting are both contemplated within the scope of thisdisclosure.

In an embodiment, the optical target 130 may include a bar 132 on whicha plurality of point light sources are mounted. The point light sourcesmay be, for example, light emitting diodes (LEDs) 134 mounted on the bar132. The bar 132 may be aluminum or a like material. The bar 132 may be1.6 meters in length and include a central strip portion 136 along whichthe LEDs 134 are mounted in a linear manner. The bar may be longer orshorter in length in other embodiments. The LEDs may emit a white light.Alternatively, the LEDs may emit monochromatic light or light with anarrow spectral bandwidth, such as an orange light. As an example andnot by limitation, six LEDs 134 may be mounted along the central stripportion 136. The six LEDs 134 may be equidistantly fitted along thecentral strip portion 136. The bar 132 may include more or less than sixLEDs in other embodiments. A power driver 138 configured to providepower to the optical target 130 from a main power source, for example,may also be mounted on the bar 132. A series of magnetic mounts may bedisposed on the back of the bar 132 to facilitate installation withceiling infrastructure. The magnetic mounts may hold the bar 132 in paceagainst a ceiling beam along with chains or other suitable securementfixings, for example. In embodiments, Bluetooth Low Energy (BLE) beaconsmay be disposed on the optical targets 130 and a BLE antenna may bedisposed on vehicle hardware to be used to scan for such signals. A BLEreceived signal strength indication (RSSI) may be used to determine anidentification between ambiguous optical targets 130 having the sameidentified code as a similar light pattern. Additionally oralternatively, WiFi signal strength may be utilized where locations ofWiFi access points are known to the localization system to determine anidentification between ambiguous optical targets 130 having the sameidentified code as a similar light pattern. As a non-limiting example,to disambiguate between non-unique targets 130, other observations maybe utilized, such as additional camera observations, laser observations,radio-wave observations, laser observations, magnetic field observation,or a combination thereof. As a non-limiting example, with respect to aplurality of non-unique targets that include the same optical code 150,disambiguation of recovered locations may be performed by computation ofa fitness-metric above a predetermined threshold and selection of thecandidate target 130 with the best fit, rank, and/or match to thefitness-metric. Those non-unique active targets 130 not within athreshold or range of the fitness-metric may be rejected while the othernon-unique active targets 130 are analyzed to determine the best fit andthus to identify a candidate optical target 130 as a best fit target. Inembodiments, the fitness-metric may be based on distances of expectedfeatures in UV space to actually observed features, on the strength ofadditional radio signals from WIFI for BLE beacon sources, and/or on aproximity of wire guidance observations. Additionally or alternatively,a system as described herein may disambiguate a location with respect toone or more candidate optical targets 130 by validating a compatibilityof aggregated odometry information with a physical shape of theinventory transit surface and static obstacles present on the inventorytransit surface. In embodiments, when an incorrect code is determinedupon failure of one or more of the LEDs of an optical target 130, forexample, rather than display of the incorrect code, an “off” code statusmay be generated and shown. For correct codes, a “correct” or “on” codestatus may be generated and shown.

The optical target 130 may include a center-fiducial marker 140 thatfacilitates measurement of a target location in a global warehousecoordinate frame stored in a map through use along with a laser distancemeter from a ground surface. An end marker 142 of the optical target 130may be colored as black, for example, or may be another contrast colorwith respect to the bar 132 of the optical target 130, such as orangewhere the bar 132 is an aluminum extrusion that is anodized black toreduce spurious reflections. The end marker 142 of the optical target130 may be used to polarize an orientation of the optical target 130without knowledge of the LED on/off pattern associated to the activeoptical target 130. Along with a code 150 associated with the opticaltarget 130 and the three-dimensional coordinates of the optical target130 to indicate target location in the warehouse environment based onthe map, the orientation of the optical target 130 is recorded in alocalization feature map for use during localization system operation.The code 150 may be unique or non-unique with respect to the opticaltarget 130.

Referring to FIG. 3, an example of a plurality of light patterns of theoptical target 130 including six LEDs 134 are shown. Each light patternmay be an optical code 150. The outer diodes may always be switched onwhile, of the inner diodes, at least one is on and at least on is off.The state of the inner diodes and the associated on/off pattern isassociated with information regarding a code of the optical target 130.A code 150 of the optical target 130 may be extracted irrespective of aviewing direction as the on/off inner diode pattern of an optical target130 does not change over time. In an embodiment, six codes may beassociated with six respective light patterns for six optical targets130. For example, as shown in FIG. 3, and with respect to the four innerdiodes from left to right, the six optical targets 130 have thefollowing pattern: Code 1 has a pattern of on/off/off/off; Code 2 has apattern of off/off/on/on; Code 3 has a pattern of off/off/on/off; Code 4has a pattern of on/off/on/on; Code 5 has a pattern of off/on/on/on; andCode 6 has a pattern of off/on/off/on. The codes may be switched tofacilitate onsite usage, such as through physical switches on theoptical target 130 or through remote control based switching, forexample.

The optical target 130 may be mounted onto ceiling infrastructure, suchas beams, purlins, and the like. Global location and orientations of themounted optical targets 130 within a map coordinate frame are measuredand recorded along with each target code 150 as, for example, arespective LED light pattern for the global localization system toutilize during vehicle operation as described herein. In an embodiment,mapping of the optical targets 130 that are mounted to the ceilinginfrastructure may occur through manual mapping utilizing a laser toolsuch as a laser range finder or laser distance meter or other suitablemapping scanning tools.

FIG. 4 illustrates a process flowchart of an embodiment of active targetusage in the GTLM along with a localization system 160. As an example,and not by way of limitation, in the localization system 160 of FIG. 4,vehicle sensors are configured to receive and process input data inblock 162 with respect to odometry as input sensor 168, laser detectionof surrounding objects as sensor input 170, and wire guidance to assistwith navigation as sensor input 172. The sensor inputs of block 162 areassociated as data that is utilized by a localization module 166 toprovide a localization for the vehicle as a normal seed update.

In step 1 of FIG. 4, a vehicle sensor is further configured to receiveand process image data of overhead features as image input 174 asdescribed herein. For example, an overhead image is captured from acamera disposed on a vehicle. Overhead feature candidates are detected,such as described in U.S. Pat. No. 9,349,181 issued on May 24, 2016,entitled LOST VEHICLE RECOVERY UTILIZING ASSOCIATED FEATURE PAIRS, andU.S. Pat. No. 9,984,467, entitled VEHICLE POSITIONING OR NAVIGATIONUTILIZING ASSOCIATED FEATURE PAIRS, issued on May 29, 2018, incorporatedby reference above. In step 2, for example, the feature candidates ofinput 178 are detections in block 176 from the overhead image that thecamera feature extraction module 164 has identified as potentialfeatures of interest, such as ceiling lights, skylights, and LEDS ofactive optical targets 130 as described herein. For example, withrespect to light detection, the feature candidates are utilized as aninput for light and skylights detection. The extracted features 184 ofthe detected light and/or skylights through block 182 may then beutilized with the associated data for localization to determine vehiclelocation in the warehouse.

With respect to the GTLM of FIG. 4, the vehicle sensor that receives andprocesses image data of overhead features specifically may receive andprocess image data associated with one or more active optical targets130, as described in greater detail below with respect to the processes500, 600 of FIGS. 5-6. In particular, step 3 of FIG. 4 sets forth anactive target detector module 180 that applies two respective processes500, 600 for active optical target 130 detection (step 4) through adetection process 500 and verification (step 5) through a verificationprocess 600 of FIG. 6. The detection process 500 of step 4 is set forthin greater detail as the detection process 500 in FIG. 5. Theverification process 600 of step 5 is set forth in greater detail as theverification process 600 in FIG. 6. The processes 500, 600 of the activetarget detector module 180 may occur within a camera feature extractionmodule 164 of the localization system 160, which extracts active opticaltargets 130 from the feature candidates of step 2. In step 4, thedetection process 500 filters input feature candidate points to removethose that are unlikely to be from one or more LEDs of active opticaltargets 130 and identifies the feature candidate points that arecandidates to be active optical targets 130 or parts of one or moreactive optical targets 130. In step 5, the verification process 600applies a method to validate each candidate found in step 4 and to findan associated displayed code, such as a respective LED light pattern.

After step 6 resulting in extracted features 184, if no active opticaltargets 130 have been found in an active target determination block 186,other localization system processes may continue in which camerafeatures in addition to sensor data, such as input odometry, laser, andwire guidance data, are fused through data association in dataassociation block 188 to estimate a location of the vehicle in an updateblock 190. However, if after step 6 one or more active optical targets130 are found in the active target determination block 186, the one ormore active optical targets 130 are combined with other ceiling lightfeatures detected by the camera feature extraction module and sent to alocalization module 166 of the localization system 160. In anembodiment, once an active target 130 is identified and matched with therespective target location coordinates in a map of the warehouse,additional camera feature extraction may be performed on other overheadfeatures as described herein, such as on lights and/or skylights. Oncean active target 130 is detected after step 6, a pose of the vehicle isdetermined and recovered in step 7 in a pose recovery block 192 based onthe active target 130. If the active target 130 has been extracted, thepose of the vehicle may be estimated from the extracted active target130 alone by projecting from a two-dimensional image frame over theoverhead image into a three-dimensional global coordinate frame andbasing the estimation on mapped target location and geometric parametersof the camera. For example, the location of the plurality of opticaltargets 130 are mapped and stored in a warehouse map prior to use of theGTLM and localization systems described herein.

A state of localized (to proceed to step 8) or lost (to proceed to step9) is determined in a state block 194. In step 8, for a localized state,the pose that is calculated from the extracted active optical target 130may be used to reseed a vehicle localization based on the extractedactive optical target 130 to ensure accurate localization in a reseedpose block 196. Such an instance may occur when the localization system160 is in a localized state but there is a disagreement between acurrent estimated pose and a pose recovered from the extracted activeoptical target 130. The recovered pose may then be used to reset thecurrent estimated pose to the recovered pose to reseed the vehiclelocalization by setting a new vehicle pose. In a recovery pose block ofstep 9, the pose that is calculated from the extracted active opticaltarget 130 may be used to reseed a current estimate pose to therecovered pose when the localization system 160 is in a lost state.

For example, while a localization system is used to provide localizationfor an industrial vehicle in an indoor warehouse environment, situationsexist in which the localization system may become lost (step 9) orotherwise unable to reliably operate. Example scenarios include where anindustrial vehicle may travel outdoors where extractable camera featuresfrom overhead ceiling features such as ceiling lights may beunavailable, or where sections of the warehouse environment in which theindustrial vehicle may travel have an insufficient density ofextractable features to maintain accurate localization. If a state ofthe localization system is lost such that the vehicle is lost, therecovered pose may be utilized as the new seed or start location forvehicle localization and navigation. After a vehicle leaves a mappedarea or loses track of mapped features, for example, the vehicle may beconsidered to be not localized. In such an instance, the active target130 may be utilized to facilitate re-localization of the vehicle uponsuccessful detection to recover the vehicle location. GTLM may beutilized in addition to or as an alternative of localization systems.For example, GTLM may be used to maximize availability of accuratelocalization provided by the localization system, for example, byproviding a reliable means to reseed the localization system to knownvehicle locations.

If the state of the localization is localized such that a vehiclelocation is known (step 8), however, the vehicle location may beverified and/or made more accurate based on the recovered pose in aglobal fix mode. For a vehicle that is localized but with low accuracy,for example, use of the active target 130 permits an increase inlocalization accuracy of a vehicle upon successful detection of theactive target 130. The active target 130 is able to be utilized toverify the predicted vehicle location and to fix the vehiclelocalization to a high degree of certainty. Such a global fix mode maysupport a localization system in a variety of manners. As a non-limitingexample, active optical targets 130 may be installed in ceilinginfrastructure locations where density of other overhead features isinsufficient for high accuracy localization with the localizationsystem. Additionally or alternatively, active targets 130 may beinstalled in locations where availability of a location fix is greatlydesirable. Increased uptime in the length of time a vehicle may belocalized through the localization system through use of such activetargets 130 enhances value of the vehicle localization in the uptime andin improving accuracy of the localization.

The processes of the active target detector module are set forth ingreater detail in the respective processes 500, 600 of FIGS. 5-6. Animage of an active optical target 130 may be projected with a lens ontoan imaging sensor and digitized as a two-dimensional image signal tocreate the overhead image. In step 1 associated with a block 502 of FIG.5 of the detection process 500, locations of LEDs of one or more imagedactive optical targets 130 are extracted in two-dimensional image spaceas “keypoint” features respectively associated with the LEDs andincluding x and y and radius dimensions alongside other overheadfeatures, such as ceiling lights and skylights. These other overheadfeatures, along with the two-dimensional image signal are processed bythe active target detector module through the detection process 500 ofstep 4 and the verification process 600 of step 5 of FIG. 4.

FIG. 5 sets forth the detection process 500 of step 4 of FIG. 4 ingreater detail as an active target candidate detection process. In step2 associated with a block 502 of the detection process 500 of FIG. 5,the detection process filters all keypoint features that are too largeto be an LED of an active optical target 130 from the overhead image.Constraints of a block 506 input into the detection process in step 2 ofthe block 504 may include a maximum keypoint feature size coefficientand a keypoint feature size fall off to indicate acceptable keypointfeature size ranges.

In step 3 associated with a block 508, the detection process 500searches in the set of remaining keypoint features for arrangements ofimaged LEDs that may be an active optical target 130 or part of anactive optical target 130. The searched information includes a set ofactive target fragments representative of a set of coordinates of imagedLEDs that represent a collinear pattern. The active target fragments arecollected and stored in a data structure, such as in a memory module.Constraints of a block 510 input into the detection process 500 in step3 associated with the block 508 may include a maximum target aspectratio, a maximum side length, and a maximum area of a bounding boxtightly fitted to the detected features associated to an active opticaltarget 130.

In step 4 associated with a block 512 of the detection process 500, theset of active target fragments is aggregated and combined into a set oflines containing potential active optical targets 130. Such anaggregation reduced an amount of data to be processed, increasingefficiency and processing speed of the active target detector module. Inembodiments, such a set of lines are not line segments, i.e., there isno start or end point but rather are infinitely long and described onlyby their angle to the horizontal coordinate axis and distance to theorigin of the coordinate system describing UV space. After performanceof the aggregation of step 4 of the block 512, all target candidates maybe collinear to one of such lines. Multiple target candidates may be onthe same line, either because there is more than one target on acomputed line, or there are other target candidates on the computedline, which in subsequent processing steps turn out to be falsedetections. These target candidates may be overlapping within a computedline, such as where one true active optical target 130 is on a line, andanother one detected active target is false, consisting of two keypointfeatures from the true active optical target 130 and one or more noisyextractions. As the localization systems described herein are notlimited to detecting only one active target per image frame, there maybe more than one such line containing active target candidates. Forinstance, there may be two parallel targets installed closeby at, forexample, a 40 cm distance, resulting in at least two lines containingactive target candidates. The aggregation of step 4 of the block 512provides for a removal of duplicates of such lines, and the aggregationparameters as the accumulation parameters of a block 514 define when twoslightly different lines may be considered equivalent. Such a slightdifference between lines may appear due to digitization effects such aspixel binning and the like. The aggregation allows for removal ofduplicate lines for processing, for example, which increases performanceefficiency and speed of subsequent steps as fewer such lines have to beprocessed.

An input into the detection process 500 in step 5 associated with ablock 516 may be a line snap distance of a block 518. As a non-limitingexample, a set of keypoint features and a set of lines as describedabove may exist in UV space. The line snap distance parameter assistswith a determination of which keypoint feature belongs to which line.For example, the line snap distance parameter may specify that akeypoint feature x belongs to a line y if the distance (i.e., length ofthe line segment of the orthogonal projection of x onto y) of x to y isless than the line snap distance. Other associations between keypointfeatures and lines using a suitable data structure are contemplated withthe scope of this disclosure.

Potential candidate active optical targets 130 are extracted from eachline of the set of lines in steps 6 and 7 respectively associated withblocks 520, 524. In step 6 associated with a block 520, inputs as targetheight and length parameters from a block 522 may include a targetheight range, a minimum acceptable target length, a maximum acceptabletarget length, and candidate height slack. By way of example and not bylimitation, step 6 is directed toward early filtering of active targetcandidates to reduce computational costs by reducing the number ofcandidates. An active target candidate is checked for a size andposition in UV space to determine that it might be an active opticaltarget 130. For instance, a row of detected ceiling lights would befiltered out at this step. For each target candidate, the system in anembodiment back-projects from UV space to 3D space to estimate thephysical size of the target candidate. This size estimate should bebetween input parameters of minimum acceptable target length and maximumacceptable target length. However, at this stage the code 150 for theactive optical target 130 may be unknown such that there is not a singleheight that could be used. Hence, the target candidates are compared tothe range of all heights of active targets in the warehouse map. Theparameter candidate height slack may specify an additional globaluncertainty on the target height estimates to make the system tolerantto estimation errors introduced by factors such as, but not limited to,slightly inaccurate camera parameters, a truck that is not exactlylevel, a mapped (measured) active target height that is not exact, andthe like. In embodiments, the processes described herein filters themost candidates that otherwise would be rejected at a later,computationally more costly stage in more efficient manner if the activetarget heights are homogeneous across all possible target codes, or ifthere is a small amount of subset with homogeneous heights (e.g.,targets installed only at 8 meters and 12 meters height).

In an embodiment, multiple candidate active optical targets 130 may beextracted from each line to facilitate extraction of active opticaltargets 130 in the presence of noise associated with noisy detections.In step 7 associated with the block 524, conflicting candidate activeoptical targets that may the result of insufficient data aggregation areeliminated. In step 8 associated with a block 526, a set of candidateactive optical targets 130 are output from the detection process 500 ofFIG. 5.

FIG. 6 sets forth the verification process 600 of step 5 of FIG. 4 ingreater detail, depicting steps of a decoding and verification processapplied to the set of candidate active optical targets 130 output fromthe detection process 500 of FIG. 5. The verification process 600follows the detection process 500 of FIG. 5 such that the set ofcandidate active optical targets 130 output in step 8 and the block 526of FIG. 5 are input in a block 602 into the verification process 600 instep 9 associated with the block 602 of FIG. 6. The verification process600 is applied to all of the set of candidate active optical targets130. Decoding and verification of the candidate active optical targets130 takes into account an optical modulation transfer function is notperfect such that a resolution of the optical system is limited and suchthat the resolution may deteriorate towards image corners.

In areas of low contrast, there may be a reduced reliability of featureextractions due to an imperfect modulation transfer. In such situations,the verification process for active target candidate verification maystart with filtering target candidates that are too small for reliabledecoding in step 10 associated with a block 604 of FIG. 6. Inputs astarget size parameter in a block 606 may include a maximum image spaceextent and radial symmetric decay. In embodiments, the maximum imagespace extent parameter relates to the size a target candidate must havein UV space for not being rejected due to unreliable decoding, such asin an example in which some LEDs were not detected when observing theactive target at a larger distance. The radial symmetric decay parametermay take into account a situation in which the image quality is best atthe center of the image and decreases towards its corners due toimperfect lenses and vignetting. The system may implement aradial-symmetric (exponential) model where the radial symmetric decayparameter specifies a magnitude of the falloff in image quality towardsthe image corners. In effect, if a target candidate is detected in theimage corner, the detected corner target candidate may be processedfurther only if the detected corner target candidate is at least biggeror longer in UV space than the maximum image space extent parameter. Anacceptable minimum target candidate size in two-dimensional image UVspace may be smaller in a center of the overhead image and increasingtoward image corners. A distance in image UV space between two detectedLEDs may be at least 2 pixels, though other larger or smaller distancesare contemplated within the scope of this disclosure.

In step 11 associated with a block 608, information stored in a patternof active target LEDs may be decoded for target candidates that are nottoo small for reliable decoding. Inputs as target point parameters froma block 610 may include tolerances for inner target point locations. Aninner points location tolerance parameter may be used in the activetarget candidate decoding subroutine. As a non-limiting example, wherethe LEDs on the physical active target are equidistantly spaced, beforedecoding the observed target candidate undergoes projection to theceiling plane for projective undistortion. This projection may not beperfect due to imperfect camera calibration or truck not being level orinstalled active targets not being level, for example. Therefore,projected LEDs may not appear perfectly equidistantly spaced in UVspace. Pixel locking effects introduced by the camera sensor maycontribute further to non-equidistantly spaced keypoint detections. Toallow the system to work with such imperfections in decoding the activetarget candidate, the system may allow the extracted features to shift acertain percentage of the active target length in UV space. For example,if a target is 100 pixel long in UV space, and an inner target pointslocation tolerance parameter is set to a value of 0.02, then detectedkeypoints of an active target will be interpreted as a LED in ‘switchedON’ configuration if located within 2 pixels of its ideal location in UVspace. In embodiments, decoding may be preceded by a perspectiveprojection of these LED point patterns onto a three-dimensional planeparallel to a floor to eliminate perspective distortion. Such aprojection may utilize calibrated camera parameters including camerapose with respect to the vehicle as an input. Any candidate activeoptical targets 130 for which no valid code is detected are rejected.

In step 12 associated with a block 612, for any successfully decodedcandidate active optical target 130, a three-dimensional representationof detected LEDs of the active optical target 130 is used to estimate aphysical size of the active optical target 130 based on a mapped heightof the candidate targets having the code. A candidate target not withina valid size range is rejected. Inputs to determine whether a candidatetarget is within a valid size range may include a minimum and maximumacceptable physical target size as physical target size acceptableparameters of a block 614.

In step 13 associated with a block 616, the verification process 600proceeds to determine whether a target image is valid. In an embodiment,such a determination is based on an image signal validation utilizingcomputing normalized cross correlation between pairwise image patchesaround detected LEDs. A system check may analyze an image signalassociated with the candidate active optical target 130 to reject falsepositive detections, for instance in high contrast image regions, suchas those regions associated with skylights. As a non-limiting example,for a detected active target candidate, all associated locations in UVspace may be computed with respect to a potential positions of one ormore active target LEDs independent of whether the active target LEDshave an on or off status. Such locations may be computed throughinterpolation in 3D space followed by a back-projection to UV space.Image patches centered at the detected or interpolated LED locations maybe selected, and dimensions of these image patches may scale with adistance between the locations and be set such that pairwise overlap ofimage patches in UV space is minimized. Suitable image similaritymetrics may be computed between pairwise image patches. By way ofexample, and not as a limitation, if the maximum of pairwisesimilarities of image patches corresponding to the one or more detectedLEDs is lower than a minimum threshold of pairwise similarities ofpatches with respect to patches corresponding to the detected and/orinterpolated LED locations, the active target detection may be rejectedto eliminate false positive rejections in block 617. The rejection inblock 617 may not be based on one or more parameters, which may beoptional. For example, alternatively, the rejection in block 617 may beparameterized with the optional image parameters of block 618, such asto provide flexibility in defining rejection criteria, as required basedon a specific image validity check scheme.

In another embodiment, the determination is based on whether thebackground is valid, and a final system check may analyze an imagesignal associated with the candidate active optical target 130 to rejectfalse positive detections in high contrast image regions, such as thoseregions associated with skylights. Inputs as image background parametersof a block 618 of optional image parameters may include a dark level lowthreshold value, a dark level high threshold value, and a targetbrightness threshold absolute value. As a non-limiting example,histograms of grey values are built from a dilated bounding box of thecandidate active optical target 130 to reject false positive detectionsbased on a histogram distribution of the grey values of the pixelswithin the aforementioned bounding box. For a determination that thetarget image of a candidate target is not valid in the block 616, thecandidate target is rejected in a block 617 and one or more othercandidate targets from the process 700 are analyzed. For a determinationthat the target image of a candidate target is valid in the block 616,the candidate target is accepted as a detected active target. In a step14 associated with a block 620, one or more detected active targets aregenerated.

Active optical targets 130 that are detected that have a code that isnot unique across a site may be analyzed as well. For such targets, alocalization system may use surrounding features to resolve an ambiguityassociated with potential locations corresponding to such active opticaltargets 130 having a similar or equivalent code or pattern.

In embodiments, the localization system may identify specific targetshaving an equivalent code by examining respective surrounding overheadfeatures such as lights and skylights to differentiate between thetargets. In such processes, an active optical target 130 may beextracted from an overhead image as described above and have arespective code identified. Centroids from any overhead features such asceiling lights in the same overhead image frame are extracted, and alllocations in a stored map having the extracted code of the extractedactive optical target 130 are determined. For each identified targetlocation with an identified extracted code, an associated pose of thevehicle is calculated. The localization system feature map is filteredand used to identify surrounding local overhead features around theoptical target 130 using the pose and to project these features to atwo-dimensional image space to be used as predictions of an activeoptical target 130. A nearest-neighbor data associated may be performedto match the predictions and overhead feature extractions from the imageframe in two-dimensional image space. Other suitable data associationmethods are contemplated within the scope of this disclosure.

Further, a pose fitness may be calculated. As an example and not alimitation, the pose fitness may be a mean match error between thepredictions and extractions, and a number of matches found may beretained. A candidate target with a best pose fitness, such as in oneexample having the smallest associated error, may be selected and passedon as the active optical target 130 to the localization system asdescribed above to determine vehicle pose. In situations where multipletargets return low and similar pose fitnesses, a number of matches fromthe data associated may be used to determine a selected active opticaltarget 130 from the options as the one with the most matches. If thenumber of matches is the same between targets, the system may reject thetarget from the overhead image or perform a plurality of additionaltests to disambiguate within the set of target candidates.

In embodiments, parameters that may affect the detection processdescribed above with respect to FIG. 5, for example, may be detectionrange and detection reliability. A spatial range of possible detectionsof a plurality of optical targets 130 may be based on a heightdifference between an installed active optical target 130 and a centerof the camera on the vehicle, the camera orientation, an active opticaltarget 130 orientation within the warehouse environment, and abrightness and spacing of LEDs on the active optical target 130. Forexample, active optical targets 130 disposed at a higher level comparedto others in a warehouse environment may permit a larger detection rangedue to a larger cone of visibility from the camera. Such higher targetsmay require brighter, further spaced LEDs to provide an image contrastsufficient for initial keypoint feature detection as described herein.For optical target 130 at a lower height range having a high LEDbrightness, a detection range may be based on a viewing direction. As anon-limiting example, viewing such a lower optical target 130 in adirection perpendicular to a direction of the target may cause lessforeshortening than viewing the lower optical target 130 in line andparallel with the direction of the target to permit larger detectionranges.

Detection reliability may be based on an amount of surrounding visualclutter that may restrict LED visibility for the LEDs on an opticaltarget 130. Racking or pipes, for example, may occlude camera view ofsuch LEDs or entire optical targets 130 to prevent detection. Inembodiments, successive subsequent frames may be analyzed to mitigate achance of incorrect detection.

In embodiments, other variant processes exist to extract active targetcandidates. A viability of these variants may depend on computationalpower available and the amount of visual clutter present in the image.Images with minimal visual clutter may permit extraction of activetargets directly from a suitable space partitioning of the extractedfeature points, which can be obtained, for instance, with a recursive2-cluster KMEANS scheme. In such a scheme, the recursive descentterminates if the expected number of LEDs has been reached or thefeature points satisfy a specific collinearity criterion in image space.Such an action induces a partition on the set of keypoint features andmay be in alternative or in addition to the aggregation step describedherein.

In embodiments, an active target may be missed in the partitiondetection scheme such that an active target candidate is not generatedif the partition separates the individual LED detections in the target.Thus, such a partition scheme may be suited to active targets wellseparated spatially from other features in UV space.

Images with higher levels of visual clutter, such as those includingextracted feature points that are not related to projections of activetarget LEDs, may undergo a more exhaustive search. As a non-limitingexample, a technique to constrain the search space in order to limitcomputational costs that may be used involves computing a Delaunaytriangulation of the extracted feature points and aggregate the edges ofthe resulting Delaunay graph as described in this disclosure. Inembodiments in which a moderate visual clutter is present in thevicinage of true active target candidates, an aggregation may beefficiently implemented by direct traversal of the Delaunay graphstarting from selected unvisited vertices in a depth-first fashion andterminate based on aforementioned collinearity criteria of currentlyvisited vertices. Due to computational costs, a fully exhaustive searchmay be permitted only for extremely cluttered scenes. In such extremelycluttered scenes, for example, there may be a high likelihood of morethan one false positive feature extraction appearing within theperimeter of a circle. The circle may include center point located atthe bisection of the two most distant adjacent true positive activetarget feature extractions and a diameter equivalent to the distance ofthese two true positive active target feature extractions.

FIG. 7 illustrates a process 700 associated with navigating and/ortracking a materials handling vehicle 100 along an inventory transitsurface 122 based on identifying an optical target from an input imageof overhead features as described herein. In an embodiment, and asdescribed herein, the materials handling vehicle 100 includes a camera102, a vehicular processor 104, a drive mechanism configured to move thematerials handling vehicle 100 along the inventory transit surface 122through, for example, the wheels 124, a materials handling mechanismconfigured to store and retrieve goods in a storage bay of the warehouse110, and vehicle control architecture in communication with the driveand materials handling mechanisms. The camera 102 is communicativelycoupled to the vehicular processor 104 and captures an input image ofoverhead features of the warehouse 110.

The vehicular processor of the materials handling vehicle executesvehicle functions, such as those set forth in the process 700. Thevehicle functions may be to retrieve camera data comprisingtwo-dimensional image information of overhead features in block 702. Forexample, a function may be to retrieve an initial set of camera datafrom the camera 102. The initial set of camera data may includetwo-dimensional image information associated with the input image ofoverhead features.

The two-dimensional image information may be matched with a plurality ofglobal target locations to generate a plurality of candidate opticaltargets 130 in block 704. For example, the two-dimensional imageinformation from the initial set of camera data may be matched with aplurality of global target locations of a warehouse map to generate theplurality of candidate optical targets 130. The global target locationsof the warehouse map may be associated with a mapping of the overheadfeatures. The warehouse map may be configured to store a position andorientation of an optical target 130 associated with each global targetlocation, and each optical target 130 may be associated with a code 150.In embodiments, each optical target 130 may include a plurality of pointlight sources, such as the LEDs 134 as described herein. The pluralityof light sources may be mounted on the bar 132 that is configured forattachment to a ceiling of the warehouse 110 as an overhead feature. Theplurality of light sources may be arranged in a pattern defining thecode 150 for each respective optical target 130. Thus, the plurality ofpoint light sources may include a light pattern as the code 150 for eachrespective optical target 130. As described herein, the plurality ofpoint light sources may be mounted on the central strip portion 136 inan equidistant and linear manner. Further as described above, theplurality of point light sources may be configured to emit a whitelight, monochromatic light, light with a narrow spectral bandwidth, orcombinations thereof.

For example, each optical target 130 may include the plurality of LEDs134. As described above, the plurality of LEDs 134 may be covered byrespective angular diffusion lenses configured to attenuate a forwardbrightness and increase an associated angular sideways brightness suchthat each LED 134 has an angular emission characteristic comprising ahigher energy emission toward angular side directions compared to aforward facing direction of each LED 134.

In embodiments, each optical target 130 may include a series of magneticmounts disposed on a back surface opposite a front surface on which theplurality of point light sources (such as the LEDs 134) are mounted, theseries of magnetic mounts configured to mount each optical target 130against a ceiling to comprise an overhead feature of the warehouse 110.As described herein, each optical target 130 may include thecenter-fiducial marker 140 configured to aid with storing of theposition of each optical target 130 in the warehouse map. Thecenter-fiducial marker 140 may be configured to be detected by a laserdistance meter disposed on and from the inventory transit surface 122 togenerate the position of each optical target 130. Further, each opticaltarget 130 may include the end marker 142 configured to aid with storingof the orientation of each optical target 130 in the warehouse map.

In block 706, the plurality of candidate optical targets 130 may befiltered to determine a candidate optical target 130, and the candidateoptical target 130 may be decoded to identify the code 150 associatedwith the candidate optical target 130. In block 708, an optical target130 associated with the identified code 150 may be identified. Further,a camera metric may be determined, the camera metric includingrepresentations of a distance and an angle of the camera 102 relative tothe identified optical target 130 and the position and orientation ofthe identified optical target 130 in the warehouse map.

In block 710, a vehicle pose may be calculated based on the identifiedoptical target 130. For example, the vehicle pose may be calculatedbased on the camera metric. In block 712, the materials handling vehicle100 may be navigated using the vehicle pose of block 710. The vehicleprocessor 104 of the materials handling vehicle 100 may further beconfigured to repeat the steps of the process 700 with a subsequent setof camera data from the camera 102 when the materials handling vehicle100 is lost. The vehicular processor 104 may execute vehicle functionsto determine if the materials handling vehicle 100 is lost, including atleast one of determining whether a seed position includes incorrectdata, and determining whether the camera data is insufficient to correctfor an error associated with an accumulated odometry associated with thematerials handling vehicle 100.

In embodiments, the vehicle processor 104 of the materials handlingvehicle 100 may further execute functions to use an accumulated odometryassociated with the materials handling vehicle 100 to update the vehiclepose to a current localized position, update a seed position as thecurrent localized position, and track the navigation of the materialshandling vehicle 100 along the inventory transit surface 122, navigatethe materials handling vehicle 100 along the inventory transit surface122 in at least a partially automated manner, or both, utilizing thecurrent localized position. The seed position may be published as thecurrent localized position on a display after updating the seed positionas the current localized position.

For the purposes of describing and defining the present disclosure, itis noted that reference herein to a variable being a “function” of aparameter or another variable is not intended to denote that thevariable is exclusively a function of the listed parameter or variable.Rather, reference herein to a variable that is a “function” of a listedparameter is intended to be open ended such that the variable may be afunction of a single parameter or a plurality of parameters.

It is also noted that recitations herein of “at least one” component,element, etc., should not be used to create an inference that thealternative use of the articles “a” or “an” should be limited to asingle component, element, etc.

It is noted that recitations herein of a component of the presentdisclosure being “configured” or “programmed” in a particular way, toembody a particular property, or to function in a particular manner, arestructural recitations, as opposed to recitations of intended use. Morespecifically, the references herein to the manner in which a componentis “configured” or “programmed” denotes an existing physical conditionof the component and, as such, is to be taken as a definite recitationof the structural characteristics of the component.

For the purposes of describing and defining the present disclosure it isnoted that the terms “substantially” and “approximately” are utilizedherein to represent the inherent degree of uncertainty that may beattributed to any quantitative comparison, value, measurement, or otherrepresentation. The terms “substantially” and “approximately” are alsoutilized herein to represent the degree by which a quantitativerepresentation may vary from a stated reference without resulting in achange in the basic function of the subject matter at issue.

Having described the subject matter of the present disclosure in detailand by reference to specific embodiments thereof, it is noted that thevarious details disclosed herein should not be taken to imply that thesedetails relate to elements that are essential components of the variousembodiments described herein, even in cases where a particular elementis illustrated in each of the drawings that accompany the presentdescription. Further, it will be apparent that modifications andvariations are possible without departing from the scope of the presentdisclosure, including, but not limited to, embodiments defined in theappended claims. More specifically, although some aspects of the presentdisclosure are identified herein as preferred or particularlyadvantageous, it is contemplated that the present disclosure is notnecessarily limited to these aspects.

It is noted that one or more of the following claims utilize the term“wherein” as a transitional phrase. For the purposes of defining thepresent disclosure, it is noted that this term is introduced in theclaims as an open-ended transitional phrase that is used to introduce arecitation of a series of characteristics of the structure and should beinterpreted in like manner as the more commonly used open-ended preambleterm “comprising.”

What is claimed is:
 1. A materials handling vehicle comprising a camera,a vehicular processor, a drive mechanism configured to move thematerials handling vehicle along an inventory transit surface, amaterials handling mechanism configured to store and retrieve goods in astorage bay of a warehouse, and vehicle control architecture incommunication with the drive and materials handling mechanisms, wherein:the camera is communicatively coupled to the vehicular processor andcaptures an input image of overhead features; and the vehicularprocessor of the materials handling vehicle executes vehicle functionsto (i) generate a plurality of candidate optical targets for an overheadfeature of the overhead features in the input image to identify theoverhead feature in the input image as a captured optical target in theinput image, wherein each optical target is associated with a code, (ii)filter the plurality of candidate optical targets for the overheadfeature to generate a ranking for each filtered plurality of candidateoptical targets; (iii) determine a candidate optical target for thecaptured optical target in the input image based on a highest ranking ofthe ranking for each filtered plurality of candidate optical targets;(iv) identify the code of the candidate optical target associated withthe highest ranking of the filtered plurality of candidate opticaltargets to determine an identified code, (v) in response to thedetermination of the identified code, identify an optical targetassociated with the identified code to determine an identified opticaltarget representative of the captured optical target in the input imageat the global target location, (vi) in response to the determination ofthe identified optical target, determine a camera metric comprisingrepresentations of a distance and an angle of the camera relative to theidentified optical target and the position and orientation of theidentified optical target in the warehouse map, (vii) calculate avehicle pose based on the camera metric, and (viii) navigate thematerials handling vehicle utilizing the vehicle pose.
 2. The materialshandling vehicle of claim 1, wherein each optical target comprises aplurality of light emitting diodes (LEDs).
 3. The materials handlingvehicle of claim 1, wherein each optical target comprises a plurality oflight emitting diodes (LEDs) covered by respective angular diffusionlenses configured to attenuate a forward brightness and increase anassociated angular sideways brightness such that each LED has an angularemission characteristic comprising a higher energy emission towardangular side directions compared to a forward facing direction of eachLED.
 4. The materials handling vehicle of claim 1, wherein each opticaltarget is a unique optical target and comprises a plurality of pointlight sources arranged in a pattern defining the code for eachrespective unique optical target as a respective unique code.
 5. Thematerials handling vehicle of claim 1, wherein: each optical targetcomprises a plurality of point light sources mounted on a bar that isconfigured for attachment to a ceiling as an overhead feature; theplurality of point light sources comprise a light pattern as the codefor each respective optical target.
 6. The materials handling vehicle ofclaim 5, wherein the plurality of point light sources are mounted on acentral strip portion in an equidistant and linear manner.
 7. Thematerials handling vehicle of claim 5, wherein the plurality of pointlight sources are configured to emit a white light, monochromatic light,light with a narrow spectral bandwidth, or combinations thereof.
 8. Thematerials handling vehicle of claim 1, wherein each optical targetcomprises a series of magnetic mounts disposed on a back surfaceopposite a front surface on which a plurality of point light sources aremounted, the series of magnetic mounts configured to mount each opticaltarget against a ceiling to comprise an overhead feature of thewarehouse.
 9. The materials handling vehicle of claim 1, wherein eachoptical target comprises a center marker configured to be detected by alaser distance meter from the inventory transit surface to generate aposition of each optical target to be stored in a warehouse map.
 10. Thematerials handling vehicle of claim 9, wherein the center marker isconfigured to be detected by the laser distance meter disposed on theinventory transit surface to generate the position of each opticaltarget.
 11. The materials handling vehicle of claim 1, wherein eachoptical target comprises an end marker configured to be detected by alaser distance meter from the inventory transit surface to generate anorientation of each optical target to be stored in a warehouse map. 12.The materials handling vehicle of claim 1, wherein the vehicularprocessor further executes vehicle functions to: (i) update the vehiclepose to a current localized position; (ii) update a seed position as thecurrent localized position; and (iii) track the navigation of thematerials handling vehicle along the inventory transit surface, navigatethe materials handling vehicle along the inventory transit surface in atleast a partially automated manner, or both, utilizing the currentlocalized position.
 13. The materials handling vehicle of claim 12,wherein the vehicular processor further executes vehicle functions topublish the seed position as the current localized position on a displayafter updating the seed position as the current localized position. 14.The materials handling vehicle of claim 1, wherein the vehicularprocessor is configured to repeat steps (i)-(viii) with a subsequent setof camera data and input image when the materials handling vehicle islost.
 15. The materials handling vehicle of claim 14, wherein thevehicular processor executes vehicle functions to determine if thematerials handling vehicle is lost, the vehicle functions comprising atleast one of: (i) determining whether a seed position comprisesincorrect data; and (ii) determining whether the camera data associatedwith the input image is insufficient to correct for an error associatedwith an accumulated odometry associated with the materials handlingvehicle.
 16. A materials handling vehicle comprising a camera, avehicular processor, a drive mechanism configured to move the materialshandling vehicle along an inventory transit surface, a materialshandling mechanism configured to store and retrieve goods in a storagebay of a warehouse, and vehicle control architecture in communicationwith the drive and materials handling mechanisms, wherein: the camera iscommunicatively coupled to the vehicular processor and captures an inputimage of overhead features; and the vehicular processor of the materialshandling vehicle executes vehicle functions to (i) generate a pluralityof candidate optical targets for an overhead feature of the overheadfeatures in the input image to identify the overhead feature in theinput image as a captured optical target in the input image, whereineach optical target is associated with a code, wherein each opticaltarget comprises a plurality of point light sources mounted on a barthat is configured for attachment to a ceiling as an overhead feature ofthe overhead features, and the plurality of point light sources comprisea light pattern as the code for each respective optical target, (ii)filter the plurality of candidate optical targets for the overheadfeature to generate a ranking for each filtered plurality of candidateoptical targets; (iii) determine a candidate optical target for thecaptured optical target in the input image based on a highest ranking ofthe ranking for each filtered plurality of candidate optical targets;(iv) identify the code of the candidate optical target associated withthe highest ranking of the filtered plurality of candidate opticaltargets to determine an identified code, (v) in response to thedetermination of the identified code, identify an optical targetassociated with the identified code to determine an identified opticaltarget representative of the captured optical target in the input imageat the global target location, (vi) in response to the determination ofthe identified optical target, determine a camera metric comprisingrepresentations of a distance and an angle of the camera relative to theidentified optical target and the position and orientation of theidentified optical target in the warehouse map, (vii) calculate avehicle pose based on the camera metric, and (viii) track the navigationof the materials handling vehicle along the inventory transit surface,navigate the materials handling vehicle along the inventory transitsurface in at least a partially automated manner, or both, utilizing thevehicle pose.
 17. The materials handling vehicle of claim 16, whereinthe plurality of point light sources are mounted on a central stripportion in an equidistant and linear manner.
 18. The materials handlingvehicle of claim 16, wherein the plurality of point light sources areconfigured to emit a white light, monochromatic light, light with anarrow spectral bandwidth, or combinations thereof.
 19. A method ofnavigating or tracking the navigation of a materials handling vehiclealong an inventory transit surface, the method comprising: disposing amaterials handling vehicle upon an inventory transit surface of awarehouse, wherein the materials handling vehicle comprises a camera, avehicular processor, a drive mechanism configured to move the materialshandling vehicle along the inventory transit surface, a materialshandling mechanism configured to store and retrieve goods in a storagebay of the warehouse, and vehicle control architecture in communicationwith the drive and materials handling mechanisms; utilizing the drivemechanism to move the materials handling vehicle along the inventorytransit surface; capturing an input image of overhead features of thewarehouse via the camera as the materials handling vehicle moves alongthe inventory transit surface; generating a plurality of candidateoptical targets for an overhead feature of the overhead features in theinput image to identify the overhead feature in the input image as acaptured optical target in the input image, wherein each optical targetis associated with a code; filtering the plurality of candidate opticaltargets for the overhead feature to generate a ranking for each filteredplurality of candidate optical targets; determining a candidate opticaltarget for the captured optical target in the input image based on ahighest ranking of the ranking for each filtered plurality of candidateoptical targets; identifying the code of the candidate optical targetassociated with the highest ranking of the filtered plurality ofcandidate optical targets to determine an identified code; in responseto the determination of the identified code, identifying an opticaltarget associated with the identified code to determine an identifiedoptical target representative of the captured optical target in theinput image at the global target location; in response to thedetermination of the identified optical target, determining a camerametric comprising representations of a distance and an angle of thecamera relative to the identified optical target and the position andorientation of the identified optical target in the warehouse map;calculating a vehicle pose based on the camera metric; and navigatingthe materials handling vehicle utilizing the vehicle pose.
 20. Themethod of claim 19, wherein: each optical target comprises a pluralityof point light sources mounted on a bar that is configured forattachment to a ceiling as an overhead feature; the plurality of pointlight sources comprise a light pattern as the code for each respectiveoptical target.